Inactivation of S-adenosylhomocysteine hydrolase by 5'-deoxy-5'-methylthioadenosine

In the coupling of ATP pyrophosphorolysis to Ca²⁺ transport in beef heart mitochondria, for each molecule of ATP cleaved, one proton is released and one Ca²⁺ is transported into the interior space. With the use of tritium labelled ATP, it could be shown that ATP is pyrophosphorylyzed into a species equivalent to Pi that moves inward, and a species equivalent to ADP that is extruded into the aqueous space on the exterior of the mitochondrion. The species equivalent to Pi has been identified as a negatively charged form of Pi (PO^?) and the species equivalent to ADP as a positively charged form (ADP⁺). The inward flow of PO^? is coupled to the inward flow of Ca²⁺ in 1:1 stoichiometry—a token that Ca²⁺ must enter in the form of Ca²⁺A^?, where A^? is a monovalent anion. During ATP pyrophosphorolysis protons are released on the I side and taken up on the M side—one proton for each molecule of ATP cleaved. The alkalinization of the matrix space leads to the deposition of Ca₃(PO₄)₂ and to the extrusion of the two species released by this deposition (Pi, K⁺). Two thirds of the PO^? is trapped as Ca₃(PO₄)₂ in the matrix space and one third is extruded into the external space. The extrusion of K⁺ provides a mechanism by which protons can be continuously brought into the matrix space to sustain a high rate of coupled pyrophosphorolysis of ATP. The coupling pattern for Ca²⁺ transport driven by ATP pyrophosphorolysis is identical with the corresponding pattern for Ca²⁺ transport driven by electron transfer. This identity is suggestive that coupling mediated by the Fo-F₁ system and coupling mediated by electron transfer complexes are mechanistically indistinguishable.